Chapter 8 LP Modeling Applications: With Computer Analyses in Excel and QM for Windows

1. Chapter 8 LP Modeling Applications: With Computer Analyses in Excel and QM for Windows Prepared by Lee Revere and John Large 8-1

2. Learning Objectives Students will be able to: • Model a wide variety of medium to large LP problems. • Understand major application areas, including marketing, production, labor scheduling, fuel blending, transportation, and finance. • Gain experience in solving LP problems with QM for Windows and Excel Solver software. 8-2

3. Chapter Outline 8.1 Introduction 8.2 Marketing Applications 8.3 Manufacturing Applications 8.4 Employee Scheduling Applications 8.5 Financial Applications 8.6 Transportation Applications 8.7 Transshipment Applications 8.8 Ingredient Blending Applications 8-3

4. Marketing Applications • Linear programming models have been used in the advertising field as a decision aid in selecting an effective media mix. • Media selection problems can be approached with LP from two perspectives. - The objective can be to maximize audience exposure or to minimize advertising costs. 8-4

5. Marketing Applications The Win Big Gambling Club • The table on the following slide presents the number of potential gamblers reached by making use of an advertisement in each of four media. • It also provides the cost per advertisement placed and the maximum number of ads that can be purchased per week. 8-5

6. Marketing Applications Medium Audience Cost Maximum Reached Per Ads Per Per Ad Ad($) Week TV spot (1 minute) 5,000 800 12 Daily newspaper (full page ad) 8,500 925 5 Radio spot (30 seconds, prime time) 2,400 290 25 Radio spot (1 minute, afternoon) 2,800 380 20 Media Selection: Win Big Gambling Club 8-6

7. Marketing Applications The Win Big Gambling Club • The total budget is $8,000. • The contractual arrangements require that at least 5 radio spots be placed each week. • Management insists that no more than $1,800 be spent on radio advertising every week. • Let X1 = # of 1-minute TV spots each week X2 = # of daily paper ads each week X3 = # of 30-second radio spots each week X4 = # of 1-minute radio spots each week 8-7

8. Win Big Gambling Club Maximize : (audience coverage) 5000 + 8500 X X 1 2 £ Subject to : X 12 (max TV spots/week ) £ 5 + 2400 + 2800 X ( max newspaper ads/week) 1 X X 2 3 4 £ 25 X ( max 30 - sec. radio spots/week ) 3 £ 20 X (max 1 - min. radio spots/week ) 4 + ³ 5 X X (min radio spots/week ) 3 4 + £ 290X 380X 1800 (max radio expense) 3 4 800 + 925 + 290 + 380 £ 8000 X X X X 1 2 3 4 (Weekly ad budget) 8-8

9. Win Big Gambling Club - QM for Windows Screen shot for problem in QM for Windows 8-9

10. Win Big Gambling Club – Solver in Excel Screen shot for Excel Formulation of Win Big’s LP Problem using Solver 8-10

11. Win Big Gambling Club – Solver in Excel Screen shot for Output from Excel Formulation. Solution of Win Big LP Problem X1 = 1.97 TV spots X2 = 5 newspaper ads X3 = 6.2 30-second radio spots X4 = 0 1-minute radio spots 8-11

12. Win Big Gambling Club – Solver in Excel • The solution gives an audience exposure of 67,240 contacts. • Because X1 and X3 are fractional, Win Big would probably round them to 2 and 6, respectively. • Situations that require all integer solutions are discussed in detail in Chapter 11. 8-12

13. Marketing Applications • Linear programming has also been applied to marketing research problems and the area of consumer research. • The next example illustrates how statistical pollsters can reach strategy decisions with LP. 8-13

14. Marketing Applications Management Sciences Associates (MSA) • The MSA determines that it must fulfill several requirements in order to draw statistically valid conclusions: • Survey at least 2,300 U.S. households. • Survey at least 1,000 households whose heads are 30 years of age or younger. • Survey at least 600 households whose heads are between 31 and 50 years of age. • Ensure that at least 15% of those surveyed live in a state that borders on Mexico. • Ensure that no more than 20% of those surveyed who are 51 years of age or over live in a state that borders on Mexico. • MSA decides that all surveys should be conducted in person. 8-14

15. Marketing Applications Management Sciences Associates (MSA) • MSA estimates that the costs of reaching people in each age and region category are as follows: MSA’s goal is to meet the sampling requirements at the least possible cost. Let: X1 = # of 30 or younger & in a border state X2 = # of 31-50 & in a border state X3 = # 51 or older & in a border state X4 = # 30 or younger & not in a border state X5 = # of 31-50 & not in a border state X6 = # 51 or older & not in a border state 8-15

16. Marketing Applications Management Sciences Associates (MSA) Objective function: minimize total interview costs = $7.5X1 + $6.8X2 + $5.5X3 + $6.9X4 + $7.25X5 + $6.1X6 subject to: X1 + X2 + X3 + X4 + X5 + X6≥ 2,300 X1 + X4≥ 1,000 X2 + X5≥ 600 X1 + X2 + X3≥ 0.15(X1 + X2 + X3 + X4 + X5 + X6) X3≤ 0.2(X3 + X6) X1, X2, X3, X4, X5, X6≥ 0 (total households) (households 30 or younger) (households 31-50 in age) (border states) (limit on age group 51+ in border state) 8-16

17. Marketing Applications Management Sciences Associates (MSA) • The computer solution to MSA’s problem costs $15,166 and is presented in the table and screen shot on the next slide, which illustrates the input and output from QM for Windows. • Note that the variables in the last two constraints are moved to the left-hand side of the inequality leaving a zero as the right-hand-side value. 8-17

18. Marketing Applications Management Sciences Associates (MSA) Computer solution for the 6 variables Input and Output from QM for Windows 8-18

19. Manufacturing Applications Production Mix • A fertile field for the use of LP is in planning for the optimal mix of products to manufacture. • A company must meet a myriad of constraints, ranging from financial concerns to sales demand to material contracts to union labor demands. • Its primary goal is to generate the largest profit possible. 8-19

20. Manufacturing Applications Fifth Avenue Industries • Four varieties of ties produced: • one is an expensive, all-silk tie, • one is an all-polyester tie, and • two are blends of polyester and cotton. • The table on the followingslideillustrates the cost and availability (per monthly production planning period) of the three materials used in the production process 8-20

21. Manufacturing Applications Fifth Avenue Industries Monthly cost & availability of material The table on the next slide summarizes the • contract demand for each of the four styles of ties, • the selling price per tie, and • the fabric requirements of each variety. 8-21

22. Manufacturing Applications Fifth Avenue Industries Data: Fifth Avenue’s goal is to maximize its monthly profit. It must decide upon a policy for product mix. Let X1 = # of all-silk ties produced per month X2 = # polyester ties X3 = # of blend 1 poly-cotton ties X4 = # of blend 2 poly-cotton ties 8-22

23. Manufacturing Applications Fifth Avenue Industries Calculate profit for each tie: Profit = Sales price – Cost per yard X Yards per tie Silk ties = $6.70 – $21 x 0.125 = $4.08 Polyester = $3.55 – $6 x 0.08 = $3.07 Poly-blend 1 = $4.31 – ($6 x 0.05 + $9 x 0.05) = $3.56 Poly-blend 2 = $4.81 – ($6 x 0.03 + $9 x 0.07) = $4.00 8-23

24. Manufacturing Applications Fifth Avenue Industries Objective function: maximize profit = $4.08X1 + $3.07X2 + $3.56X3 + $4.00X4 Subject to: 0.125X1≤ 800 0.08X2 + 0.05X3 + 0.03X4≤ 3,000 0.05X3 + 0.07X4≤ 1,600 X1≥ 6,000 X1≤ 7,000 X2≥ 10,000 X2≤ 14,000 X3≥ 13,000 X3≤ 16,000 X4≥ 6,000 X4≤ 8,500 X1, X2, X3, X4≥ 0 8-24

25. Manufacturing Applications Fifth Avenue • Using Solver in Excel, the computer-generated solution is to produce • 6,400 all-silk ties each month; • 14,000 all-polyester ties; • 16,000 poly–cotton blend 1 ties; and • 8,500 poly–cotton blend 2 ties. • This produces a profit of $160,020 per production period. • See Programs 8.3A and 8.3B on the next page for details. 8-25

26. Manufacturing Applications Fifth Avenue Formulation for Fifth Avenue Industries LP Problem Using Solver 8-26

27. Manufacturing Applications Fifth Avenue Excel Output for Solution to the LP Problem 8-27

28. Fifth Avenue QM for Windows 8-28

29. Manufacturing Applications Production Scheduling • This type of problem resembles the product mix model for each period in the future. • The objective is either to maximize profit or to minimize the total cost (production plus inventory) of carrying out the task. • Production scheduling is well suited to solution by LP because it is a problem that must be solved on a regular basis. • When the objective function and constraints for a firm are established, the inputs can easily be changed each month to provide an updated schedule. 8-29

30. Manufacturing Applications Production Scheduling • Setting a low-cost production schedule over a period of weeks or months is a difficult and important management problem. • The production manager has to consider many factors: • labor capacity, • inventory and storage costs, • space limitations, • product demand, and • labor relations. • Because most companies produce more than one product, the scheduling process is often quite complex. 8-30

31. Employee Scheduling Applications Assignment Problems • Assignment problems involve finding the most efficient assignment of • people to jobs, • machines to tasks, • police cars to city sectors, • salespeople to territories, and so on. • The objective might be • to minimize travel times or costs or • to maximize assignment effectiveness. • We can assign people to jobs using LP or use a special assignment algorithm discussed in Chapter 10. 8-31

32. Employee Scheduling Applications Assignment Problems • Assignment problems are unique because • they have a coefficient of 0 or 1 associated with each variable in the LP constraints; • the right-hand side of each constraint is always equal to 1. • The use of LP in solving assignment problems, as shown in the example that follows, yields solutions of either 0 or 1 for each variable in the formulation. 8-32

33. Assignment ProblemIvan and Ivan Law Firm Example • The law firm maintains a large staff of young attorneys. • Ivan, concerned with the effective utilization of its personnel resources, seeks some objective means of making lawyer-to-client assignments. • Seeking to maximize the overall effectiveness of the new client assignments, Ivan draws up the table on the following slide, in which the estimated effectiveness (on a scale of 1 to 9) of each lawyer on each new case is rated. 8-33

34. Assignment ProblemIvan and Ivan Law Firm Example { 1 if attorney i if assigned to case j Xij = 0 otherwise Ivan’s Effectiveness Ratings To solve using LP, double-subscripted variables are used. Let where i = 1,2,3,4 for Adams, Brooks, Carter, and Darwin, respectively j = 1,2,3,4 for divorce, merger, embezzlement, and exhibitionism, respectively 8-34

35. Assignment ProblemIvan and Ivan Law Firm Example = 6X11 + 2X12 + 8X13 + 5X14 + 9X21 + 3X22 + 5X23 + 8X24 + 4X31 + 8X32 + 3X33 + 4X34 + 6X41 + 7X42 + 6X43 + 4X44 The LP formulation follows: maximize effectiveness Coefficients correspond to effectiveness table Darwin has a rating of 6 in Divorce Subject to: X11 + X21 + X31 + X41 = 1 (divorce case) X12 + X22 + X32 + X42 = 1 (merger) X13 + X23 + X33 + X43 = 1 (embezzlement) X14 + X24 + X34 + X44 = 1 (exhibitionism) X11 + X12 + X13 + X14 = 1 (Adams) X21 + X22 + X23 + X24 = 1 (Brooks) X31 + X32 + X33 + X34 = 1 (Carter) X41 + X42 + X43 + X44 = 1 (Darwin) 8-35

36. Assignment ProblemIvan and Ivan Law Firm Example The law firm’s problem can be solved in QM for Windows and Solver in Excel. There is a total effectiveness rating of 30 by letting X13 = 1, X24 = 1, X32 = 1, and X41 = 1. All other variables are equal to zero. QM for Windows Solution Output 8-36

37. Employee Scheduling Applications Labor Planning • Labor planning problems address staffing needs over a specific time period. • They are especially useful when managers have some flexibility in assigning workers to jobs that require overlapping or interchangeable talents. • Large banks frequently use LP to tackle their labor scheduling. 8-37

38. Alternate Optimal Solutions • Alternate optimal solutions are common in many LP problems. • The sequence in which you enter the constraints into QM for Windows can affect the solution found. • No matter the final variable values, every optimal solution will have the same objective function value. 8-38

39. Financial Applications Portfolio Selection • The selection of specific investments from a wide variety of alternatives is a problem frequently encountered by • managers of banks, • mutual funds, • investment services, and • insurance companies. • The manager’s overall objective is usually to maximize expected return on investment • given a set of legal, policy, or risk restraints. 8-39

40. Financial ApplicationsPortfolio Selection International City Trust (ICT) • ICT has $5 million available for immediate investment and wishes to do two things: (1) maximize the interest earned on the investments made over the next six months, and (2) satisfy the diversification requirements as set by the board of directors. 8-40

41. Financial ApplicationsPortfolio Selection International City Trust (ICT) The specifics of the investment possibilities are as follows: • Also, the board specifies that • at least 55% of the funds invested must be in gold stocks and construction loans, and that • no less than 15% be invested in trade credit. 8-41

42. Financial ApplicationsPortfolio Selection International City Trust (ICT) Formulate ICT’s decision as an LP problem. Let X1 = dollars invested in trade credit X2 = dollars invested in corporate bonds X3 = dollars invested in gold stocks X4 = dollars invested in construction loans The objective function formulation is presented on the next slide. 8-42

43. Financial ApplicationsPortfolio Selection International City Trust (ICT) Objective: maximize dollars of interest earned = 0.07X1 + 0.11X2 + 0.19X3 + 0.15X4 subject to: X1≤ 1,000,000 X2 < 2,500,000 X3 < 1,500,000 X4 < 1,800,000 X3 + X4 > 0.55(X1+X2+X3+X4) X1 > 0.15(X1+X2+X3+X4) X1 + X2 + X3 + X4 < 5,000,000 X1, X2, X3, X4 > 0 SOLUTION: Maximum interest is earned by making X1 = $750,000, X2 = $950,000, X3 = $1,500,000, and X4 = $1,800,000. Total interest earned = $712,000 8-43

44. Transportation Applications Shipping Problem • Transporting goods from several origins to several destinations efficiently is called the “transportation problem.” • It can be solved with LP or with a special algorithm introduced in Chapter 10. • The transportation or shipping problem involves determining the amount of goods or items to be transported from a number of origins to a number of destinations. 8-44

45. Transportation Applications Shipping Problem • The objective usually is to minimize total shipping costs or distances. • Constraints in this type of problem deal with capacities at each origin and requirements at each destination. • The transportation problem is a very specific case of LP; a special algorithm has been developed to solve it. 8-45

46. Transportation ApplicationsShipping Problem The Top Speed Bicycle Co. • The firm has final assembly plants in two cities in which labor costs are low, • New Orleans and Omaha. • Its three major warehouses are located near the large market areas of • New York, Chicago, and Los Angeles. • The sales requirements and factory capacities for each city are as follows: CITYDEMANDCAPACITY New York 10,000 NA Chicago 8,000 NA Los Angeles 15,000 NA New Orleans NA 20,000 Omaha NA 15,000 8-46

47. Transportation ApplicationsShipping Problem The Top Speed Bicycle Co. • The cost of shipping one bicycle from each factory to each warehouse differs, and these unit shipping costs are as follows: From To New Orleans Omaha New York $2 $3 Chicago $3 $1 Los Angeles $5 $4 • The company wishes to develop a shipping schedule that will minimize its total annual transportation costs. 8-47

48. Transportation ApplicationsShipping Problem The Top Speed Bicycle Co. Let X11 = bicycles shipped from New Orleans to New York X12 = bicycles shipped from New Orleans to Chicago X13 = bicycles shipped from New Orleans to Los Angeles X21 = bicycles shipped from Omaha to New York X22 = bicycles shipped from Omaha to Chicago X23 = bicycles shipped from Omaha to Los Angeles • In a transportation problem, there will be one constraint for each demand source and one constraint for each supply destination. 8-48

49. Transportation ApplicationsShipping Problem The Top Speed Bicycle Co. Objective: Minimize total shipping costs = 2X11 +3X12 + 5X13 + 3X21 + 1X22 + 4X23 Subject to: X11 + X21 = 10,000 X12 + X22 = 8,000 X13 + X23 = 15,000 X11 + X12 + X13≤ 20,000 X21 + X22 + X23≤ 15,000 All variables > 0 8-49

50. Transportation ApplicationsShipping Problem The Top Speed Bicycle Co. • Using Solver in Excel, the computer-generated solution to Top Speed’s problem is shown in the following table and in the screen shot on the next slide. • The total shipping cost is $96,000. New Orleans Omaha New York 10,000 0 Chicago 0 8,000 Los Angeles 8,000 7,000 From To 8-50